CH709757A2 - Dynamometer control of a couple for watchmakers screw driver, use and set of watchmaker tools. - Google Patents

Abstract

A dynamometer (1) for controlling a torque for a watchmaker's screwdriver according to the invention comprises a driving part (4), a driven part and a device for measuring a torque between the driving and driven parts. This control dynamometer (1) has the shape of a ring able to be threaded and thus removably mounted on a watchdog screwdriver handle (2). The driven part is provided with coupling means provided for coupling to the clockmaker's screwdriver handle (2) so as to allow a rotation drive of the watchdog screwdriver handle (2) by the driven part, when the control dynamometer is mounted on the watchdog screwdriver handle (2). The invention also relates to a set of watchmaker tools including a control dynamometer according to the invention as well as the use of such a dynamometer to authorize the driving of a clockmaker's screwdriver handle.

Description

Technical field of the invention

The present invention relates to the field of instruments for watchmaking. More precisely, it concerns a torque control dynamometer for a watchmaker's screwdriver, its use, as well as a set of watchmaker's tools.

State of the art

[0002] The watchmaker's screwdrivers are precision screwdrivers specially designed for use in watchmaking. Some of them are called "dynamometric" because they are equipped with a device to control the tightening torque or loosening of a screw.

More specifically, a watchdog torque screwdriver indicates that a torque reaches a particular value. Often, it is not adjustable, in the sense that this particular value can not be changed. When this is the case, the watchmaker's torque screwdriver must often be supplemented by others that do not have the same caliber as him.

[0004] There are also adjustable watchdog torque screwdrivers. As a counterpoint to their greater versatility, these adjustable watchdog torque screwdrivers have a disadvantage, which is that their adjustment is long and tedious. In addition, adjustable torque screwdrivers are even more expensive than non-adjustable torque screwdrivers.

[0005] Furthermore, a torque watchdog screwdriver generally makes it possible to carry out a torque level check only in one direction. However, the torque applied during a tightening and which may have to be controlled during this tightening is oriented in the screwing direction, while the control that a tightening already achieved is sufficient is carried out in the unscrewing direction. It follows that there are two types of torque watchdog screwdrivers. Torque screwdrivers of a first type make it possible to control current tightenings, which they serve to realize. Torque screwdrivers of a second type make it possible to check the sufficiency or not of tightenings already made.

When bidirectional, a watchdog torque screwdriver provides a torque control in the screwing direction and a torque control in the unscrewing direction. However, a bidirectional watchdog torque screwdriver has the same gauge in the screwing direction and in the unscrewing direction. In other words, a bidirectional watchdog torque screwdriver is provided to indicate that the torque it applies reaches a predetermined value, which is the same regardless of the direction of this torque. However, avoiding excessive tightening of a screw in the screwing direction requires a comparison of the tightening torque to a first predetermined value, while then checking that the tightening of the same screw is sufficient is performed by comparing a torque loosening to a second predetermined value, which is less than the first. It follows that, even when bidirectional, the same watchdog torque screwdriver can not be used for a check to prevent excessive tightening of a screw, then for a check to check the adequacy of the tightening of the screw. this screw.

Moreover, each watchmaker's screwdriver can be equipped only with tools or bits having a particular diameter, while there are several tool diameters or wick.

A watchmaker's tool may therefore include one or more non-torque screwdrivers, several non-adjustable torque screwdrivers of different calibres, several screwdrivers of the same caliber but equipped with tools or bits of different diameters and several torque screwdrivers of different senses, possibly supplemented by one or more adjustable torque screwdrivers.

Summary of the invention

The invention is at least intended to provide a new opportunity to compose a watchmaker's tools.

According to the invention, this object is achieved by means of a dynamometer of i control of a torque for a watchmaker's screwdriver, comprising: a driving part, which is at least partially uncovered so that it can be driven manually, a driven part, which is pivotally mounted about a pivot axis, relative to the driving part, and which is coupled to this driving part so that a driving torque in rotation about the pivot axis can be transmitted from the driving part to the driven part, and a device for measuring said torque.

This control dynamometer has the shape of a ring able to be threaded and thus removably mounted on a watchdog screwdriver handle. The driven part is provided with coupling means provided for coupling to the clockmaker's screwdriver handle so as to allow the watchmaker's handle to be driven by the driven part in a rotation on the pivot axis. , when the control dynamometer is mounted on the watchdog screwdriver handle.

Several control dynamometers according to the invention may be of different calibres, that is to say allow clamping checks with respect to different predetermined values. They can alternatively equip the same watchmaker's screwdriver.

Also, a control dynamometer according to the invention can be used with a first screwdriver, then with a second screwdriver, which may not be equipped with the same tool or wick as the first. Each of these two screwdrivers can also be used without a control dynamometer.

Advantageously, several control dynamometers according to the invention can be removably mounted on the same watchmaker's screwdriver, which then has several possible uses without mounting or dismounting operation between them.

The control dynamometer defined above may incorporate one or more other advantageous characteristics, alone or in combination, in particular among those specified below.

Advantageously, the control dynamometer comprises immobilization means provided for immobilizing the control dynamometer on the watchdog screwdriver handle, in the longitudinal direction of the handle.

Advantageously, the immobilizing means comprise a member forming an annular bead which projects in an axial passage for the clockmaker's screwdriver handle and which is at least partially retractable elastically out of this axial passage. Such immobilizing means can have a simple constitution, compact and / or economic, while being able to allow easy installation of the control dynamometer on a watchmaker's handle and / or an easy adjustment of its longitudinal position on the handle .

Advantageously, the coupling means comprise at least one projection of interconnection, projecting into an axial passage for the watchdog screwdriver handle. When this is the case, the rotational coupling between the control dynamometer and the clockmaker's screwdriver handle may be the result of a clutch which can have a simple, compact and / or economical constitution, while allowing a easy installation of the control dynamometer on a clockmaker's screwdriver handle and / or an easy adjustment of its longitudinal position on this handle.

A clutch and a longitudinal immobilization by engagement of a retractable bead in an annular groove complement each other and have their own operations that are compatible with each other and that can contribute to obtaining ease of implementation and removal of the control dynamometer and / or ease of adjustment of the longitudinal position of the control dynamometer.

Advantageously, the control dynamometer comprises an envelope enclosing the measuring device. Preferably, the driving part comprises a wall which surrounds an axial passage for the screwdriver handle and which forms an outer portion of the envelope. Preferably, the driven part comprises a wall which delimits the axial passage and which forms an inner portion of the envelope. When this is so, the control dynamometer can have a simple and robust constitution, while being compact.

[0021] Advantageously, the control dynamometer is a torque limiter. The measuring device couples the driving and driven parts as long as said torque is below a predetermined value. The measuring device disengages so as to leave the driving piece free to rotate relative to the driven part as soon as the torque reaches the predetermined value.

The invention also relates to a set of watchmaker tools, comprising a watchdog screwdriver handle and a control dynamometer as defined above. This control dynamometer can be threaded and thus removably mounted on the clockmaker's screwdriver handle. The coupling means are able to mate with the clockmaker's screwdriver handle so as to allow the watchmaker's handle to be driven by the driven part, in a rotation on the pivot axis, when the Control dynamometer is mounted threaded on the watchmaker's screwdriver handle.

The watchmaker tooling set defined above may incorporate one or more other advantageous characteristics, alone or in combination, in particular among those defined below.

Advantageously, the control dynamometer has two possible mounting directions on the clockmaker's screwdriver handle. Being particularly advantageous in the case where the control dynamometer is unidirectional, this means that this control dynamometer can be mounted alternately in two opposite directions on the watchdog screwdriver handle. Mounted in the first of these two directions, the control dynamometer can be unidirectional and operational in the direction of a screwing. Mounted in the second direction, the control dynamometer can be unidirectional and operational in the sense of unscrewing.

[0025] Advantageously, the watchmaker tool set comprises a clutch capable of coupling the driven part to the watchmaker's screwdriver handle. Preferably, the clockmaker's screwdriver handle comprises at least one external longitudinal groove forming a female part of a clutch complementary to the clutch relief. This clutch relief and the external longitudinal groove are part of the clutch.

Advantageously, the clockmaker's screwdriver handle comprises at least one outer annular groove forming complementary immobilization means of the bead of the control dynamometer. The bead and the outer annular groove are such that they together achieve an immobilization in the longitudinal direction, by reversible engagement of the bead in the outer annular groove, when the control dynamometer is mounted threaded on the watchdog screwdriver handle.

Advantageously, the clockmaker's screwdriver handle comprises several copies of the outer longitudinal groove and several copies of the outer annular groove. Preferably, the copies of the outer longitudinal groove and the copies of the outer annular groove intersect and together form a cross-knurling.

The invention also relates to a use of a control dynamometer as defined above. In this use, this control dynamometer is threaded and thus removably mounted on a watchdog screwdriver handle. The coupling means couples the driven part to the watchmaker's screwdriver handle so as to allow a rotation drive of the watchdog screwdriver handle by the driven part.

Brief description of the drawings

Other advantages and features will emerge more clearly from the following description of a particular embodiment of the invention given by way of non-limiting example and shown in the accompanying drawings, among which: <tb> fig. 1 <SEP> is a side view of an assembly according to the invention and resulting from the assembly of a watchmaker's screwdriver and a dynamometer, which is more precisely a torque control dynamometer and which is also in accordance with the invention, <tb> fig. 2 <SEP> is a perspective view of the control dynamometer shown in FIG. 1, <tb> fig. 3 <SEP> is a lateral view, with axial half-section, and represents the same control dynamometer as FIG. 2, <tb> fig. 4 <SEP> is a perspective view of the watchmaker's screwdriver of FIG. 1 without the dynamometer control of FIGS. 2 and 3, and <tb> fig. 5 <SEP> is a side view on which the watchmaker's screwdriver of FIG. 4 is equipped with two examples of the dynamometer control of FIGS. 2 and 3.

Description of a preferred embodiment of the invention

In FIG. 1, a dynamometer 1 for controlling a tightening or loosening torque is mounted removably on the handle 2 of a watchdog screwdriver 3. A coupling between the control dynamometer 1 and the handle 2 is then operational, thanks to which this control dynamometer 1 can rotate the watchmaker's screwdriver 3 and rotate it on its longitudinal axis.

According to the invention, the control dynamometer 1 has the general shape of a ring, as can be seen in FIG. 2 where he is represented alone. This ring can be threaded and thus removably mounted on a complementary watchmaker's screwdriver handle, such as the handle 2.

As can be seen easily in FIG. 3, the control dynamometer 1 comprises two annular and coaxial parts, which are pivotally mounted relative to each other and which are an external driving part 4 and a driven part 5 surrounded by this driving part 4. The reference X -X denotes the pivot axis about which the driven part 5 pivots with respect to the driving part 4. This pivot axis X-X coincides with the axis of rotation around which the control dynamometer 1 rotates when rotates the watchmaker's screwdriver 1. A succession of external splines 6 to facilitate a manual drive of the control dynamometer 1 between two fingers are formed in the driving part 4, at its peripheral surface.

Schematized by a rectangle in FIG. 3, a torque measuring device 7 couples the driven part 5 to the driving part 4. This measuring device 7 is a dynamometric device known per se and, in what follows, it will not be described in detail for the sake of simplification. . The driven part 5 and the driving part 4 together form an envelope enclosing the measuring device 7.

The measuring device 7 may be disengageable, which is the case in the example shown where the control dynamometer 1 is more precisely a torque limiter. When it is thus disengageable, the measuring device 7 couples the driving part 4 and the workpiece 5 as long as the torque between them is less than a predetermined value. The measuring device 7 disengages so as to leave the driving part free to rotate with respect to the driven part as soon as the torque between the driving part 4 and the driven part 5 reaches the predetermined value.

The control dynamometer 1 is bidirectional, which means that the measuring device 7 is able to indicate that a torque has reached a predetermined value regardless of the direction in which this torque is exerted around the body. X-X pivot axis.

Still in fig. 3, the driving part 4 and the driven part 5 surround a through axial passage 8 for the handle 2. This axial passage 8 is substantially centered on the pivot axis X-X. The driven part 5 carries an internal elastic ring 9 for immobilizing the control dynamometer 1 on the handle 2, parallel to the pivot axis X-X. This elastic ring 9 is mounted in an internal groove 10 of the driven part 5 so as to project partially inwards and thus form a bead projecting in the axial passage 8. This bead can retract into the internal groove 10, outside the axial passage 8, by elastically compressing the elastic ring 9 against the bottom of this internal groove 10.

The coupling between the control dynamometer 1 and the handle 2 is more precisely a coupling between the driven part 5 and the handle 2. In the example shown, it is the fact of a clutch, the built-up part by the driven part has rigid lugs 11 forming jaw clutch reliefs. Centripetal and identical, the dog clutch lugs 11 project in the axial passage 5, radially, towards the pivot axis X-X. Advantageously four in number as in the example shown, the dog clutch lugs 4 are evenly distributed angularly around the axial passage 8, as can be seen in FIG. 2.

The driving part 4 and the driven part 5 can each be made of stainless steel. The elastic ring 9 is made of elastomer, for example acrylonitrile-butadiene copolymer (NBR), also called nitrile rubber.

The watchmaker's screwdriver 3 is shown alone in FIG. 4. Its handle 2 comprises an elongate body 20 and a rotary head 21, which equips an end of this body 20 and which is provided for the support of the index finger of a hand using the watchmaker's screwdriver 1 to screw or unscrew a screw. Opposite the rotary head 20, the other end of the body 20 has means 22 for fixing a tool 23 which, in the example shown, can be dismantled and which, once worn out, can thus be replaced by a new tool 23.

On a part of its length, the body 20 defines a handle 24, which is also a receiving portion of one or more control dynamometer 1. At the handle 24, the body 20 comprises a circumferential succession of external longitudinal grooves 25, each of which has a complementary cross section of any clutch pin 11. These longitudinal grooves 25 constitute a second part of the clutch whose clutch lugs 11 constitute a first part, as specified above.

Always at the level of the handle 24, the body 20 comprises a longitudinal succession of external annular grooves 26, each of which has a complementary cross section of the protruding bead that the elastic ring 9 at rest forms outside the internal groove 10. Each external annular groove 26 and the elastic ring 9 form complementary means of immobilization of the control dynamometer 1 on the handle 24, in the longitudinal direction of the handle 2.

The longitudinal grooves 25 and the annular grooves 26 intersect each other in the manner of a lace, so that their presence results in a knurling covering the handle 24 and facilitating manual gripping. The longitudinal grooves 25 are deeper than the annular grooves 26, in which the clutch lugs 11 can not engage by rotating the driven part 5 relative to the handle 2. The handle 24 can be made of stainless steel. The same can be true of the rest of the watchmaker's screwdriver 3.

The watchmaker's screwdriver 3 can be used as it is, that is to say without control dynamometer 1.

A control dynamometer 1 can also be threaded on the handle 2 to be mounted on the handle 24. To do this, each clutch pin 11 must be engaged in a longitudinal groove 25. With a transient radial compression, the elastic ring 9 can cross one or more annular rows of bumps separating the annular grooves 26 from each other. In this way, the control dynamometer 1 has an adjustable position along the handle 24.

In FIG. 1, a control dynamometer 1 is mounted on the handle 24. The pivot axis X-X then coincides substantially with the longitudinal axis of the watchdog screwdriver 3. The clutching lugs 11 are engaged in four longitudinal grooves 25 and the clutch comprising them performs an operational coupling, whereby the control dynamometer 1 can rotate the watchmaker's screwdriver 3 and rotate it on its longitudinal axis.

In FIG. 1, the handle 2 carries only one control dynamometer 1. To simultaneously tighten a screw and control this tightening, the user maneuvers the watchdog screwdriver 3 via the control dynamometer 1, in the screwing direction, for example between one inch and the middle finger of his right or left hand, while pressing the index finger of this hand on the rotating head 21 so as to hold the watchmaker's screwdriver 3 in engagement with the screw to tighten. When the predetermined value is reached, the measuring device 7 disengages and no longer couples the driving part 4 to the driven part 5 maneuvered by the user.

Still in fig. 1, the control dynamometer 1 can also be used to check that a screw already in place is sufficiently tight. To evaluate a tightening already performed, the user actuates the driving part 4 in the direction of unscrewing, while the watchdog screwdriver 3 provided with the control dynamometer 1 is engaged with the screw. If the tightening of this screw is sufficient, the measuring device 7 disengages without the watchdog screwdriver 3 could be rotated in the unscrewing direction.

Still in FIG. 1, the control dynamometer 1 can be replaced by a control dynamometer 1 identical except for its caliber. In other words, the screwdriver 1 may be equipped alternately with several control device 1 whose respective measuring devices 7 do not disengage at the same predetermined value.

Furthermore, the control dynamometer 1 can be removed from the watchmaker's screwdriver 3 and then be mounted on another watchmaker's screwdriver, provided with a tool having a mounting tail of larger diameter than the tool 23. .

For example, ten control dynamometers 1 of different calibres and ten watchmaker's screwdrivers 3 that can receive different tool diameters make it possible to obtain a hundred different combinations. Prior to the invention, these hundred different combinations could be obtained by means of hundreds of different torque screwdrivers.

In FIG. 5, the handle 2 carries two control dynamometers 1. One of these two control dynamometers 1 is provided to control a torque in the direction of a screwing, while the other control dynamometer 1 is provided to control a torque in the direction of unscrewing. The control dynamometer 1 provided for controlling a torque in the direction of a screwing is of a slightly larger size than the control dynamometer 1 provided for controlling a torque in the direction of unscrewing. In this way, the two control dynamometers 1 mounted on the same handle 2 can be used successively for the same screws, one during screwing and tightening to avoid excessive tightening, then the other to verify that this tightening is sufficient.

Alternatively, the control device 1 may be unidirectional, that is to say, can perform a torque control in one direction. When this is the case, we reverse the mounting direction of the control dynamometer 1 on the handle 2 when we want to reverse the direction in which the dynamometer can perform a torque control. Mounted in a first direction, the control dynamometer 1 is oriented to control a torque in the direction of a screwing. Mounted in the other direction, the control device 1 is oriented to control a torque in the direction of unscrewing.

Claims (11)

A torque control dynamometer for a watchmaker's screwdriver, comprising: - a driving part (4), which is at least partially discovered so as to be manually driven, - a driven part (5), which is pivotally mounted about a pivot axis (X-X), relative to the driving part (4), and which is coupled to this driving part (4) so that a rotational driving torque about the pivot axis (X-X) can be transmitted from the driving part (4) to the driven part (5), and A device (7) for measuring said torque, characterized in that it has the shape of a ring capable of being threaded and thus removably mounted on a watchdog screwdriver handle (2), the driven part (5) being provided with coupling means (11) adapted to mate with the watchmaker's screwdriver handle (2) so as to allow the clockmaker's screwdriver handle (2) to be driven by the driven part (5) in a rotation on the axis when the control dynamometer is mounted on the watchdog screwdriver handle (2). 2. Dynamometer control according to claim 1, characterized in that it comprises immobilization means (9) provided for immobilizing the control dynamometer on the watchdog screwdriver handle (2), in the longitudinal direction of this watchmaker's screwdriver handle (2). 3. Dynamometer control according to claim 2, characterized in that the immobilizing means comprise a member (9) forming an annular bead which is projecting into an axial passage (8) for the watchdog screwdriver handle (2). ) and which is at least partially retractable elastically out of this axial passage (8). 4. Dynamometer control according to any one of the preceding claims, characterized in that the coupling means comprise at least one clutch projection (11), projecting into an axial passage (8) for the screwdriver handle of watchmaker (2). 5. Dynamometer control according to any one of the preceding claims, characterized in that it comprises a casing enclosing the measuring device (7), the driving part (4) having a wall which surrounds an axial passage (8) for the screwdriver handle and which forms an outer portion of the casing, the driven part (5) having a wall which defines the axial passage (8) and which forms an inner portion of the casing. 6. Dynamometer control according to any one of the preceding claims, characterized in that the control dynamometer is a torque limiter, the measuring device (7) coupling the driving parts (4) and led (5) as said torque is less than a predetermined value, the measuring device (7) declutching so as to leave the driving part (4) free to rotate relative to the driven part (5) as soon as the torque reaches the predetermined value. 7. Set of watchmaker's tools, comprising a clockmaker's screwdriver handle (2), characterized in that it comprises a control dynamometer (1) according to any one of the preceding claims, this control dynamometer ( 1) being able to be threaded and thus removably mounted on the clockmaker's screwdriver handle (2), the coupling means (11) being able to couple with the watchmaker's screwdriver handle (2) in such a way that to allow a drive of this watchdog screwdriver handle (2) by the driven part (5), in a rotation on the pivot axis (X-X), when the control dynamometer (1) is mounted on on the watchmaker's screwdriver handle (2). 8. Set of screwdriver according to claim 7, the control dynamometer (1) according to claim 4, the watchmaker tool assembly comprising a clutch (11, 25) able to couple the driven part (5). ) with the clockmaker's screwdriver handle (2), the clockmaker's screwdriver handle (2) comprising at least one longitudinal groove (25) forming a female clutch complementary part of the clutch relief (11), this relief of interconnection (11) and the outer longitudinal groove (25) forming part of the clutch. 9. Set of watchmaker tools according to any one of claims 7 and 8, the control dynamometer (1) according to claim 3, the watchdog screwdriver handle (2) having at least one annular groove. external device (26) forming complementary immobilization means for the bead of the control dynamometer (1), the bead and the external annular groove (26) being such that they together achieve an immobilization in the longitudinal direction, by reversible engagement of the bead in the outer annular groove (26), when the control dynamometer (1) is mounted on the watchdog screwdriver handle (2). 10. watchmaker tooling set according to claims 8 and 9, wherein the clockmaker's screwdriver handle (2) comprises several copies of the outer longitudinal groove (25) and several copies of the outer annular groove (26). , the copies of the outer longitudinal groove (25) and the copies of the outer annular groove (26) intersecting and forming a cross-knurling together. 11. Use of a control dynamometer (1) according to any one of claims 1 to 6, wherein the control dynamometer (1) is threaded and thus mounted removably on a watchdog screwdriver handle (2). ), the coupling means (11) coupling the driven part (5) to the watchmaker's screwdriver handle (2) so as to allow a rotation drive of the watchdog screwdriver handle (2) by the driven part (5).